KR101368642B1 - pyrotechnic self-destruct device of sub-munition - Google Patents

Abstract

The present invention relates to a chemical bomb detonation apparatus of chatan. Specifically, the fuse body 10 and the self-explosion body is provided with a self-explosion tube fixed to the upper portion of the body of the body, the slider 20 is elastically installed to be movable inside the fuse body, and is provided in the slider Periodic width pipe 30 for detonating the connecting pipe in the body of the body and delay code installed in the self-expanding pipe so that not only self-detonation when the bomb is deactivated due to the impact function, but also disables the self-expanding pipe when the slider is unloaded. And a loading pin 50 installed on the fuse body so as to load the slider and ignite the delay code assembly. According to this configuration, it is possible to minimize the space constraint, to realize sufficient performance at low cost, to minimize the incidence rate, and to disable the detonation fuse even when the slider is unloaded, thereby facilitating the testing of the detonation tube and the testing of the detonation device. It's effective.

Description

Pyrotechnic self-destruct device of sub-munition

The present invention relates to a chemical bomb detonation apparatus of jatan, which minimizes spatial constraints, implements sufficient performance at low cost, minimizes misfire, and disables the detonation fuse by allowing the detonation fuse to be detonated even when the slider is unloaded. It relates to a chemical detonating device of chatan.

It is based on the high explosives charged inside the main body of the bomb and it is released from the mother in the air and acts as a shock function in the event of a ground collision. It is equipped with a chemical self-destructing device which ignites the delayed cord and discharges itself after a certain period of time if the bomb is not detonated by the impact function after reaching the ground.

Currently developed and used electronic self-destructing devices are expensive, because the drive, battery, electronics, EED, etc. are added.

On the other hand, chemical detonators are manufactured with only a driving device and a delay tube, so they can be manufactured at low cost. Although chemical detonators are difficult to apply to high emission altitudes due to limited delay time due to space constraints, they are widely used for the purpose of killing horses or penetrating armor (eg armored vehicles or tanks).

As an example of a chemical bomb detonation apparatus of the conventional jatan, Korean Patent Publication No. 1997-0001239 and Korean Patent Registration No. 10-0306357 are disclosed.

The Korean Patent Publication No. 1997-0001239 is a device in which a slider is installed in a housing fixed to the upper part of the main body so as to repel a periodic width pipe in which the submerged screw is mounted on the slider. Is installed by the elastic member so as to be rotatable and the rotor is rotated by the elastic force of the elastic member as the slider is pulled out of the housing by sequentially inserting the auxiliary explosion pipe, the ignition gun, the delay gunpowder, and the connecting gun gun inside the slider. In this way, the sinking can detonate the auxiliary aeration pipe.

The Korean Patent No. 10-0306357 is an apparatus for detonating a periodic width tube through a sinking screw by horizontally installing a slider filled with a periodic width tube inside a housing fixedly installed through a stud on an upper portion of the main body. A delay pipe assembly is sequentially installed in the accommodating groove filled with ignition gunpowder, delay gunpowder, and connection gunpowder. On one side of the slider is rotated with the inertia generated during the horizontal movement of the slider out of the housing. The striker is designed to hit the auxiliary detonator pipe to transfer heat energy.

As described above, the conventional chemical bomb detonation device has a limitation in that the delay code is implemented in the slider and the delay time due to the space limitation is limited, and the slider is hit by the striker as the slider is loaded. There was a problem that the fuse didn't function because the striker didn't work.

Accordingly, the present invention has been made to solve the above problems, and the present invention minimizes spatial constraints, realizes sufficient performance even at low cost, minimizes incidence, and enables self-detonation fuses to be disabled even when the slider is unloaded. It is an object of the present invention to provide a chemical detonating device of chatan that facilitates the process of neutralizing the fuse and the testing of the detonating device.

The self-explosive detonating device of jatan according to the present invention has a fuse body and a self-exploding body and is fixed to an upper portion of the jatan body, a self-extinguishing pipe, a slider elastically installed to be movable inside the fuse body, and in the slider. A periodic width pipe installed to detonate the connection pipe in the detonation body, and a delay code provided in the detonation body to detonate the self-explosion pipe when the slider is unloaded by the impact function as well as detonation of the slider. It includes a delay code assembly provided, and a loading pin installed on the fuse body to ignite the delay code assembly while loading the slider.

The fuse body is provided with a first immersion assembly for activating the periodic width tube in response to the release of the loading pin, and the second immersion assembly for activating the delay cord assembly is installed in the suicide body.

The fuse body is provided with a self-amplifying device for detonating by the delay code assembly and the period explosives inside the slider.

The delay cord assembly includes an ignition end cap with an ignition gunpowder, a delay cord with a delay gunpowder, and an end cap with a coupling gun, and the ignition end cap is screwed at one end of the delay cord. The end cap is screwed to the other end of the delay cord.

The delay cord assembly is arranged in the fuse body in a bent form to increase the delay time by maximizing the space utilization inside the fuse body to increase its length.

In accordance with the present invention, the chemical detonation apparatus of the charcoal minimizes spatial constraints, realizes sufficient performance even at low cost, minimizes misfire rate, and disables the detonation fuse by disabling the detonation fuse even when the slider is unloaded. There is an effect of facilitating the treatment and testing of the suicide device.

In addition, since the chemical explosion-proof device of the jatan according to the present invention is installed in a self-expanding fuse fixedly installed on the upper part of the body, and modularized together with the fuse body, it is possible to separate the self-explosion device and test and verify the performance. Simultaneous assembly and test evaluation are possible by separating main function and self-destructing function by delay code.

In addition, the chemical self-destructing apparatus of chatan according to the present invention is advantageous in terms of assembly and production since the delay code assembly is manufactured in a state in which caps are assembled at both ends of the delay code.

In addition, the self-explosive detonation device of the bullet according to the present invention is released at the same time when the loading pin is released, the slider loading and the detonation of the detonation device is operated at the same time to ensure the reliability of operation.

1 is a perspective view showing a self-expanding fuse is applied to the chemical explosion-proof device of the chatan according to the present invention,
Figure 2 is a plan sectional view showing the interior of the fuse body of Figure 1 (unloaded state of the slider),
Figure 3 is an internal configuration of the suicide body of Figure 1,
4 is a configuration diagram (partly internal) of the delay code assembly of FIG.
5 is an operating state diagram of FIG. 2 (slider loading state),
Figure 6 is a perspective view showing a bullet applied to the present invention,
7 is a state diagram in which a parachute is assembled to the self-expanding tube of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a perspective view showing a self-explosion fuse is applied to the chemical explosion-proof self-explosion device of the bullet in accordance with the present invention, Figure 2 is a cross-sectional view (slider unloaded state) showing the inside of the fuse body of Figure 1, Figure 3 is the self-destruction of Figure 1 6 is a perspective view showing the inner shell to which the present invention is applied.

As shown, the chemical detonating device according to the present invention is a self-explosive body 15 is installed in the self-explosion tube (2) fixed to the upper portion of the jatan body (1) is modularized with the fuse body (10), the A slider 20 elastically installed to allow horizontal movement in the fuse body 10 and a connecting pipe 11 (shown in FIG. 7) installed in the slider 20 to protrude into the shell body 1. The detonating periodic width pipe 30 and the bomb bombardment are installed on the detonation body 15 so as not only to detonate when not in operation due to the impact function, but also to disable the fuse body 10 even when the slider 20 is unloaded. A delay code assembly 40 having a delay code 42, and a loading pin 50 installed on the fuse body 10 to load the slider 20 and ignite the delay code assembly 40; Equipped.

The fuse body 10 is a flat cylindrical shape, the loading pin 50 is installed in the vertical direction in the center thereof, the inside of the slider 20 by the slider spring 21 elasticity to be slidable in the horizontal direction Is installed.

In addition, the fuse body 10 is a direction in which the first immersion assembly 60-1 operating the periodic width pipe 30 by the ground impact after the release of the loading pin 50 is perpendicular to the slider 20. Is installed, the suspending body 15 is provided with a second sediment assembly (60-2) for operating the delay code assembly 40.

In addition, the fuse body 10 is provided with a self-detonation detonation tube 70 for detonating the period width tube 30 by the delay code coupling 40.

The delay cord assembly 40 includes an ignition end cap 41 with an ignition gun 41a, a delay cord 42 with a delay gun 42a, and a self-detonation width within the fuse body 10. The end cap 43 with the connecting gun 43a connected to detonate the tube 70 is sequentially connected, and the ignition end cap 41 is screwed to one end of the delay cord 42. The end cap 43 is screwed to the other end of the delay cord 42.

The delay code assembly 40 is disposed in the susceptible body 15 in a bent shape to increase the delay time by maximizing the space utilization within the suspicion body 15 to increase its length.

The loading pin 50 is provided with the self-loading pin 51 is extended to the outside, the second pinning assembly (60-2) is assembled to the self-destructing body 15 to the self-loading pin 51 The sinking support lever 52 is installed. In addition, on the upper portion of the loading pin 50, after the release of charcoal releases the loading pin 50 by the aerodynamic force to move the slider 20 while releasing the sinking support lever 52 to release the second sinking assembly (60-2) A parachute (P: shown in Fig. 7) is installed to operate.

The submerged support lever 52 is fixed so that the second submerged assembly 60-2 is not operated. The susceptible body 15 is inertial so that the second submerged assembly 60-2 is not operated before the loading is completed. A weight 81, a centrifugal lock 82, and a fastener 83 are provided.

The detonator amplification pipe 70 is disposed at the end cap 43 of the delay code assembly 40 is operated by the explosive force of the connecting powder 43a of the end cap 43.

The first and second sinking assemblies 60-1 and 60-2, the inertia weights, the centrifugal locks 81 and 82, and the catch 83 are respectively operated by elastic springs.

According to the self-explosion fuse to which a chemical bomb explosion device of the bullet according to the present invention configured as described above is applied, if the bomb is not normally detonated by the impact function after the slider is loaded, the bomb is detonated after a certain time delay through the delay code assembly. It is possible to minimize the incidence rate, and to expedite the explosion of the self explosive detonator and the main detonation tube after a certain delay even in the state that the slider is not loaded.

In the present invention, since the delay code assembly is disposed in the self-destructive body in a bent U-shape to increase the delay time by maximizing the space utilization within the self-exploding body and increasing its length, the space constraint is minimized and the cost is low. Implement sufficient performance

In addition, the present invention is installed in the self-explosion fuse fixed to the upper body of the self-explosion body is modularized together with the fuse body, so that it can be separated by the self-explosion device itself, test evaluation and performance confirmation, the main function and the impact Simultaneous assembly and test evaluation are possible by separating the self-destructing function by the delay code, and the delay code assembly is advantageous in terms of assembly and production since the cap is assembled at both ends of the delay code.

In addition, the self-explosive detonation device of the bullet according to the present invention is released at the same time when the loading pin is released, the slider loading and the detonation of the detonation device is operated at the same time to ensure the reliability of operation.

Hereinafter, the operation of the chemical explosion-proof self-detonation device of the bullet in accordance with the present invention will be described in detail.

Firstly, the inertial weight 81 is released by the backward inertia force and the centrifugal lock 82 is released by the rotational force until the charcoal is discharged from the mother, and the charcoal is released from the mother in the air.

The released bullets are subjected to aerodynamics through the parachute (P) while falling freely from the air above the ground, by which the loading pin 50 is released and the slider 20 in the fuse body 10 is moved to complete the loading. do. 5 shows a state in which the slider 20 and the periodic width pipe 30 provided in the slider 20 are moved and loaded.

On the other hand, while the loading pin 50 is released and the submerged support lever 52 installed in the suicide body 15 is pulled out, the second submerged assembly 60-2 is operated so that the second submerged assembly 60-2 is released. An end portion (simmering portion) strikes the ignition end cap 41 of the delay cord assembly 40 and ignites the gunpowder of the delay cord assembly 40.

Thereafter, ground bombs are caused by a ground collision, and the collision of the first sinking assembly 60-1 strikes the main explosion tube 30 and the high explosives in the shell body through the connecting pipe 11 (shown in FIG. 7). By this explosion, operation by the impact which is the main function of the bomb is made, and the bomb is exploded.

When the periodic width pipe does not operate normally due to ground collision of the bullet, after the predetermined delay time passes through the delay code 42 of the delay code assembly 40, the end cap of the delay code assembly 40 43 is ignited by the explosive powder (43a) to detonate the self-detonator tube 70, the explosion force of the self-detonator tube 70 is transmitted to the main period tube 30 through the passage to the main period tube 30 is detonated Self-destruction and neutralization function is achieved.

Although the present invention has been described with reference to the embodiments shown in the drawings, these are merely exemplary, and various modifications and equivalent other embodiments are possible, as well as those skilled in the art. The technical protection scope should be defined by the technical spirit of the appended claims.

10: fuse body 11: connector
15: suicide body 20: slider
30: period width pipe 40: delay code assembly
41: ignition end cap 42: delay code
43: end cap 50: loading pin
51: self-loading pin 52: sinking support lever
60-1: first submerged assembly 60-2: second submerged assembly
70: suicide bomber

Claims (4)

A self-exploding fuse having a fuse body and a self-exploding body and fixedly installed on the upper body of the body;
A slider that is elastically installed to be movable inside the fuse body;
A periodic width pipe installed in the slider to detonate a connecting pipe in the suicide body;
A delay code assembly having a delay code provided on the self-expanding fuse to not only self-detonate when the bomb is inoperable due to the impact function but also to disable the self-expanding fuse when the slider is unloaded,
And a loading pin installed on the fuse body to ignite the delay code assembly at the same time as loading the slider,
The delay code assembly includes an ignition end cap with an ignition gunpowder, a delay code with a delay gunpowder, and an end cap with a built-in gunpowder,
The ignition end cap is screwed to one end of the delay cord, and the end cap is screwed to the other end of the delay cord, so that the self-expanding tube, slider, periodic width tube, and delay code assembly are detachably modularized between the respective components.
The fuse body is provided with a first immersion assembly for operating the cycle width tube in accordance with the release of the loading pin,
The suspending body is provided with a second sediment assembly for operating the delay cord assembly,
The delay cord assembly is a self-explosive detonator of the charcoal, characterized in that arranged in the fuse body bent to increase the delay time by maximizing the space utilization inside the fuse body to increase the length. delete delete delete

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